A magnetic field sensor includes a reference-field-sensing circuit channel that allows a self-test or a self-calibration of the circuitry of the magnetic field sensor. The self-test or the self calibration can have at least two different bandwidths that provide a respective at least two different rates of self-test or self-calibration.

Patent
   9201122
Priority
Feb 16 2012
Filed
Feb 16 2012
Issued
Dec 01 2015
Expiry
May 19 2033
Extension
458 days
Assg.orig
Entity
Large
50
129
currently ok
1. A magnetic field sensor, comprising:
a magnetic field sensing element configured to generate a magnetic field signal in response to a magnetic field;
a primary circuit path coupled to receive and to process the magnetic field signal, the primary circuit path comprising a circuit parameter;
a clock frequency generator configured to generate a redistribution clock signal with a first redistribution clock frequency during a first time period and with a second different redistribution clock frequency during a second time period;
a feedback circuit path coupled at both ends to the primary circuit path and forming a feedback loop, wherein the feedback circuit path comprises:
a switched capacitor circuit coupled to receive the redistribution clock signal, the switched capacitor circuit forming an integrator, the switched capacitor circuit comprising a selectable unity gain frequency having a first unity gain frequency related to the first redistribution clock frequency during the first time period and having a second unity gain frequency related to the second redistribution clock frequency during the second time period, wherein the feedback circuit path is configured to generate an output signal coupled to calibrate the circuit parameter with first and second rates related to the first and second unity gain frequencies.
27. A method of adjusting a rate of a calibration or a rate of a self-test of a magnetic field sensor, comprising:
generating, with a magnetic field sensing element, a magnetic field signal in response to a magnetic field;
receiving and processing the magnetic field signal with a primary circuit path comprising a circuit parameter;
generating a redistribution clock signal with a first redistribution clock frequency during a first time period and a with a second different redistribution clock frequency during a second time period;
generating an output signal coupled to calibrate the circuit parameter with a feedback circuit path coupled at both ends to the primary circuit path and forming a feedback loop, wherein the feedback circuit path comprises:
a switched capacitor circuit coupled to receive the redistribution clock signal, the switched capacitor circuit forming an integrator, the switched capacitor circuit comprising a selectable unity gain frequency having a first unity gain frequency related to the first redistribution clock frequency during the first time period and having a second unity gain frequency related to the second redistribution dock frequency during the second time period, wherein the output signal is operable to calibrate the circuit parameter with first and second rates related to the first and second unity gain frequencies.
2. The magnetic field sensor of claim 1, wherein the clock frequency generator is further configured to generate a sample clock signal with a sample clock frequency during the first and second time periods, wherein the switched capacitor circuit is coupled to receive the sample clock signal, and wherein the switched capacitor circuit further comprises a notch characteristic, the notch characteristic having a notch frequency related to the redistribution clock frequency.
3. The magnetic field sensor of claim 2, wherein the second redistribution clock frequency is lower than the first redistribution clock frequency.
4. The magnetic field sensor of claim 2, wherein the clock frequency generator is configured to generate the redistribution clock signal with more than two redistribution clock frequencies to result in a respective more than two unity gain frequencies of the switched capacitor circuit, resulting in a respective more than two rates of calibration of the circuit parameter at a respective more than two different times.
5. The magnetic field sensor of claim 2, wherein the first time period begins at a time proximate to a startup of the magnetic field sensor, and wherein the second time period begins at a time proximate to an end of the first time period.
6. The magnetic field sensor of claim 2, wherein the magnetic field sensor is disposed proximate to a target object, wherein the magnetic field sensor is configured to sense a movement of the target object, wherein the first time period begins at a time proximate to a first movement of the target object, and wherein the second time period begins at a time proximate to an end of the first time period.
7. The magnetic field sensor of claim 2, wherein the circuit parameter calibrated by the feedback circuit path comprises a sensitivity of the primary circuit path to the magnetic field.
8. The magnetic field sensor of claim 7, further comprising a drive circuit configured to generate a voltage signal or a current signal, wherein the magnetic field sensing element is coupled receive the voltage signal or the current signal, wherein the feedback circuit path is configured to control the voltage signal or the current signal to calibrate the sensitivity of the primary circuit path to the magnetic field.
9. The magnetic field sensor of claim 2, wherein the circuit parameter calibrated by the feedback circuit path comprises an offset voltage of the primary circuit path.
10. The magnetic field sensor of claim 9, wherein the electronic circuit further comprises an offset circuit configured to generate a control voltage, wherein the primary circuit path further comprises an amplifier coupled to receive the control voltage, wherein the feedback circuit path is configured to control the control voltage to calibrate the offset voltage of the primary circuit path.
11. The magnetic field sensor of claim 2, wherein the first unity gain frequency and the second unity gain frequency are selected to provide loop stability.
12. The magnetic field sensor of claim 2, wherein the magnetic field sensing element comprises at least two Hall effect elements.
13. The magnetic field sensor of claim 2, wherein the magnetic field sensing element comprises at least two magnetoresistance elements.
14. The magnetic field sensor of claim 2, wherein the magnetic field sensing element comprises at least two magnetic field sensing elements, wherein the primary circuit path further comprises:
a first switching circuit coupled to the at least two magnetic field sensing elements, wherein the first switching circuit is configured to couple the at least two magnetic field sensing elements into a measured-field-sensing configuration and into a reference-field-sensing configuration, wherein the first switching circuit is operable to switch back and forth alternately between the measured-field-sensing configuration and the reference-field-sensing configuration at a first switching rate to provide the magnetic field signal, wherein the first switching circuit is configured to generate the magnetic field signal comprising:
a measured-magnetic-field-responsive signal portion responsive to a measured magnetic field when coupled in the measured-field-sensing configuration; and
a reference-magnetic-field-responsive signal portion responsive to a reference magnetic field when coupled in the reference-field-sensing configuration.
15. The magnetic field sensor of claim 14, wherein the reference magnetic field comprises first and second reference magnetic fields pointing in opposite directions at locations of selected ones of the at least two magnetic field sensing elements, the magnetic field sensor further comprising:
a magnetic field generator operable to generate the first and second reference magnetic fields.
16. The magnetic field sensor of claim 15, wherein the magnetic field generator comprises:
at least two reference field conductor portions, each proximate to a respective one of the at least two magnetic field sensing elements, wherein the at least two reference field conductor portions are configured to carry a reference current to generate the reference magnetic field, wherein the reference magnetic field comprises at .least two reference magnetic field portions having respective magnetic field directions directed in opposite directions.
17. The magnetic field sensor of claim 16, wherein the primary circuit path further comprises:
a second switching circuit coupled to provide the reference current, wherein the second switching circuit is operable to alternately switch the reference current between a first reference current direction and a second opposite reference current direction synchronously with the first switching rate.
18. The magnetic field sensor of claim 16,
wherein the magnetic field signal, during measurement time periods, is representative of the measured-magnetic-field-responsive signal portion and, during reference time periods interleaved with the measurement time periods at a rate synchronous with the first switching rate, is representative of the reference-magnetic-field-responsive signal portion, wherein
the primary circuit path is time multiplexed to select and to process the signal representative of the measured-magnetic-field-responsive signal portion during the measurement time periods, and wherein
the feedback circuit path is time multiplexed to select and to process the signal representative of the reference-magnetic-field-responsive signal portion. during the reference time periods.
19. The magnetic field sensor of Claim 18, wherein the primary circuit path is configured to generate a first sensor output signal representative of the measured-magnetic field-responsive signal portion, and wherein the feedback circuit path is configured to generate a second different sensor output signal representative of the reference-magnetic-field-responsive signal portion.
20. The magnetic field sensor of claim 16, wherein the first switching circuit is configured to couple the at least two magnetic field sensing elements to have respective opposite directions of responses to a magnetic field when coupled in the reference-field-sensing configuration, and wherein the first switching circuit is configured to couple the at least two magnetic field sensing elements to have respective same directions of responses to a magnetic field when coupled in the measured-field-sensing configuration.
21. The magnetic field sensor of claim 16, wherein the at least two magnetic field sensing elements are supported by a substrate, and wherein the at least two reference field conductor portions comprise a conductor supported by the substrate and proximate to the magnetic field sensing element.
22. The magnetic field sensor of claim 21, wherein the at least two reference field conductor portions span more than one metal layer supported by the substrate.
23. The magnetic field sensor of claim 16, wherein the at least two magnetic field sensing elements are supported by a substrate, and wherein the at least two reference field conductor portions comprise a conductor separate from but proximate to the substrate.
24. The magnetic field sensor of claim 16, wherein the measured magnetic field is generated by a measured current carried by a measured-current conductor.
25. The magnetic field sensor of claim 1, Wherein the first time period begins at a time proximate to a startup of the magnetic field sensor, and wherein the second time period begins at a time proximate to an end of the first time period.
26. The magnetic field sensor of claim 1, wherein the magnetic field sensor is disposed proximate to a target object, wherein the magnetic field sensor is configured to sense a movement of the target object, wherein the first time period begins at a time proximate to a first movement of the target object, and wherein the second time period begins at a time proximate to an end of the first time period.
28. The method of claim 27, further comprising:
generating a sample clock signal with a sample clock frequency during the first and second time periods, wherein the switched capacitor circuit is coupled to receive the sample clock signal, and wherein the switched capacitor circuit further comprises a notch characteristic, the notch characteristic having a notch frequency related to the redistribution clock frequency.
29. The method of claim 28, wherein the second redistribution clock frequency is lower than the first redistribution clock frequency.
30. The method of claim 28, wherein the generating the redistribution clock signal comprises:
generating the redistribution clock signal with more than two redistribution clock frequencies to result in a respective more than two unity gain frequencies of the switched capacitor circuit, resulting in a respective more than two rates of calibration of the circuit parameter at a respective more than two different times.
31. The method of claim 28, wherein the first time period begins at a time proximate to a startup of the magnetic field sensor, and wherein the second time period begins at a time proximate to an end of the first time period.
32. The method of claim 28, wherein the magnetic field sensor is disposed proximate to a target object, wherein the first time period begins at a time proximate to a first movement of the target object, and wherein the second time period begins at a time proximate to an end of the first time period.
33. The method of claim 28, wherein the circuit parameter calibrated by the output signal comprises a sensitivity of the primary circuit path to the magnetic field.
34. The method of claim 28, wherein the circuit parameter calibrated by the feedback circuit path comprises an offset voltage of the primary circuit path.
35. The method of claim 28, wherein the first unity gain frequency and the second unity gain frequency are selected to provide loop stability.
36. The method of claim 28, wherein the magnetic field sensing element comprises at least two Hall effect elements.
37. The method of claim 28, wherein the magnetic field sensing element comprises at least two magnetoresistance elements.
38. The method of claim 28, wherein the magnetic field sensing element comprises at least two magnetic field sensing elements, wherein the receiving and the processing the magnetic field signal with the primary circuit path further comprises:
coupling, with a first switching circuit, the at least two magnetic field sensing elements into a measured-field-sensing configuration and into a reference-field-sensing configuration, wherein the coupling, with the first switching circuit, is operable to switch back and forth alternately between the measured-field-sensing configuration and the reference-field-sensing configuration at a first switching rate to provide the magnetic field signal comprising:
a measured-magnetic-field-responsive signal portion responsive to a measured magnetic field when coupled in the measured-field-sensing configuration; and
a reference-magnetic-field-responsive signal portion responsive to a reference magnetic field when coupled in the reference-field-sensing configuration.
39. The method of claim 38, wherein the reference magnetic field comprises first and second reference magnetic fields pointing in opposite directions at locations of selected ones of the at least two magnetic field sensing elements.
40. The method of claim 39, further comprising:
generating the reference magnetic field with a magnetic field generator comprising:
at least two reference field conductor portions, each proximate to a respective one of the at least two magnetic field sensing elements, wherein the at least two reference field conductor portions are configured to carry a reference current to generate the reference magnetic field, wherein the reference magnetic field comprises at least two reference magnetic field portions having respective magnetic field directions directed in opposite directions.
41. The method of claim 40, further comprising:
alternately switching, with a second switching circuit, the reference current between a first reference current direction and a second opposite reference current direction synchronously with the first switching rate.
42. The method claim 40,
wherein the magnetic field signal, during measurement time periods, is representative of the measured-magnetic-field-responsive signal portion and, during reference time periods interleaved with the measurement time periods at a rate synchronous with the first switching rate, is representative of the reference-magnetic-field-responsive signal portion, wherein
the primary circuit path is time multiplexed to select and to process the signal representative of the measured-magnetic-field-responsive signal portion during the measurement time periods, and wherein
the feedback circuit path is time multiplexed to select and to process the signal representative of the reference-magnetic-field-responsive signal portion during the reference time periods.
43. The method of claim 42, wherein the primary circuit path is configured to generate a first sensor output signal representative of the measured-magnetic-field-responsive signal portion, and wherein the feedback circuit path is configured to generate a second different sensor output signal representative of the reference-magnetic-field-responsive signal portion.
44. The method of claim 40, wherein the coupling, with the first switching circuit, comprises:
coupling the at least two magnetic field sensing elements to have respective opposite directions of responses to a magnetic field when coupled in the reference-field-sensing configuration; and
coupling the at least two magnetic field sensing elements to have respective same directions of responses to a magnetic field when coupled in the measured-field-sensing configuration.
45. The method of claim 40, wherein the at least two magnetic field sensing elements are supported by a substrate, and wherein the at least two reference field conductor portions comprise a conductor supported by the substrate and proximate to the magnetic field sensing element.
46. The method of claim 45, wherein the at least two reference field conductor portions span more than one metal layer supported by the substrate.
47. The method of claim 40, wherein the at least two magnetic field sensing elements are supported by a substrate, and wherein the at least two reference field conductor portions comprise a conductor separate from but proximate to the substrate.
48. The method of claim 40, wherein the measured magnetic field is generated by a measured current carried by a measured-current conductor.
49. The method of claim 27, wherein the first time period begins at a time proximate to a startup of the magnetic field sensor, and wherein the second time period begins at a time proximate to an end of the first time period.
50. The method of claim 27, wherein the magnetic field sensor is disposed proximate to a target object, wherein the first time period begins at a time proximate to a first movement of the target object, and wherein the second time period begins at a time proximate to an end of the first time period.

Not Applicable.

Not Applicable.

This invention relates generally to magnetic field sensors and, more particularly, to magnetic field sensors that use adjustable feedback for self-calibrating or self-testing with an adjustable time constant.

As is known, there are a variety of types of magnetic field sensing elements, including, but not limited to, Hall effect elements, magnetoresistance elements, and magnetotransistors. As is also known, there are different types of Hall effect elements, for example, planar Hall elements, vertical Hall elements, and circular Hall elements. As is also known, there are different types of magnetoresistance elements, for example, anisotropic magnetoresistance (AMR) elements, giant magnetoresistance (GMR) elements, tunneling magnetoresistance (TMR) elements, Indium antimonide (InSb) elements, and magnetic tunnel junction (MTJ) elements.

Hall effect elements generate an output voltage proportional to a magnetic field. In contrast, magnetoresistance elements change resistance in proportion to a magnetic field. In a circuit, an electrical current can be directed through the magnetoresistance element, thereby generating a voltage output signal proportional to the magnetic field.

Magnetic field sensors, which use magnetic field sensing elements, are used in a variety of applications, including, but not limited to, a current sensor that senses a magnetic field generated by a current carried by a current-carrying conductor, a magnetic switch (also referred to herein as a proximity detector) that senses the proximity of a ferromagnetic or magnetic object, a rotation detector that senses passing ferromagnetic articles, for example, gear teeth, and a magnetic field sensor that senses a magnetic field density of a magnetic field. Particular magnetic field sensor arrangements are used as examples herein. However, the circuits and techniques described herein apply also to any magnetic field sensor.

As is known, some integrated circuits have internal built-in self-test (BIST) capabilities. A built-in self-test is a function that can verify all or a portion of the internal functionality of an integrated circuit. Some types of integrated circuits have built-in self-test circuits built directly onto the integrated circuit die. Typically, the built-in self-test is activated by external means, for example, a signal communicated from outside the integrated circuit to dedicated pins or ports on the integrated circuit. For example, an integrated circuit that has a memory portion can include a built-in self-test circuit, which can be activated by a self-test signal communicated from outside the integrated circuit. The built-in self-test circuit can test the memory portion of the integrated circuit in response to the self-test signal.

Conventional built-in self-test circuits used in magnetic field sensors tend not to test the magnetic field sensing element used in the magnetic field sensor. Conventional built-in self-test circuits also tend not to test all of the circuits with a magnetic field sensor.

Some magnetic field sensors employ self-calibration techniques, for example, by locally generating a calibration magnetic field with a coil or the like, measuring a signal resulting from the calibration magnetic field, and feeding back a signal related to the resulting signal to control a gain of the magnetic field sensor. Several self-calibration arrangements are shown and described in U.S. Pat. No. 7,923,996, entitled “Magnetic Field Sensor With Automatic Sensitivity Adjustment,” issued 26, 2008, and assigned to the assignee of the present invention. Also U.S. patent application Ser. No. 12/840,324, entitled “Circuits and Methods For Generating A Diagnostic Mode Of Operation In A Magnetic Field Sensor,” filed Jul. 21, 2010, U.S. patent application Ser. No. 12/706,318, entitled “Circuits and Methods for Generating a Self-Test of a Magnetic Field Sensor,” filed Feb. 16, 2010, and U.S. patent application Ser. No. 13/095,371, entitled “Circuits and Methods for Self-Testing or Self-Calibrating a Magnetic Field Sensor,” filed Apr. 27, 2011, each assigned to the assignee of the present invention, teach various arrangements of coils and conductors disposed proximate to magnetic field sensing elements and used to generate self-test magnetic fields. The above patent and applications also teach various multiplexing arrangements. These applications and patent, and all other patent applications and patents described herein, are incorporated by reference herein in their entirety.

Typically, a self-test or a self-calibration of a magnetic field sensor takes place at a single rate or during a single predetermined time period (i.e., with a single bandwidth). In some applications, this single rate, when used for self-calibration, may result in the magnetic field sensor being inaccurate for a substantial amount of time following a power up of the magnetic field sensor. However, speeding up the self-test or the self-calibration, i.e., increasing the bandwidth of the self-calibration would result in the magnetic field sensor being less accurate and having a higher output noise level.

Also typically, self-test and/or self-calibration of the magnetic field sensor must be performed when the magnetic field sensor is not sensing a sensed magnetic field, i.e., when the magnetic field sensor is not operating in its regular sensing mode.

It would be desirable to provide built in self-test and/or self-calibration circuits and techniques in a magnetic field sensor that allow the self-test and self-calibration functions to test and calibrate a magnetic field sensor at a fast rate (i.e., within a short time period) while not reducing resolution and while not increasing output noise level.

It would also be desirable to provide built in self-test and/or self-calibration circuits and techniques in a magnetic field sensor that allow the self-test and self-calibration to occur while the magnetic field sensor is operating in its regular sensing mode.

It would also be desirable to be able to perform the built in self-test and self-calibration regardless of a magnitude of an external magnetic field.

It would also be desirable to provide built in self-test circuits and techniques in a magnetic field sensor that allow the self-test function to test a magnetic field sensing element used within the magnetic field sensor.

It would also be desirable to provide built in self-test circuits and techniques in a magnetic field sensor that allow the self-test all of the circuits within the magnetic field sensor.

The present invention can provide built in self-test and/or self-calibration circuits and techniques in a magnetic field sensor that allow the self-test and self-calibration functions to test and calibrate a magnetic field sensor at a fast rate (i.e., within a short time period) while not reducing resolution and while not increasing output noise level.

The present invention can also provide built in self-test and/or self-calibration circuits and techniques in a magnetic field sensor that allow the self-test and self-calibration to occur while the magnetic field sensor is operating in its regular sensing mode.

The present invention can also perform the built-in self-test and self-calibration regardless of a magnitude of an external magnetic field.

The present invention can also provide built in self-test circuits and techniques in a magnetic field sensor that allow the self-test function to test a magnetic field sensing element used within the magnetic field sensor.

The present invention can also provide built in self-test circuits and techniques in a magnetic field sensor that allow the self-test all of the circuits within the magnetic field sensor.

In accordance with one aspect of the present invention, a magnetic field sensor includes a magnetic field sensing element configured to generate a magnetic field signal in response to a magnetic field. The magnetic field sensor also includes a primary circuit path coupled to receive and to process the magnetic field signal. The primary circuit path has a circuit parameter. The magnetic field sensor also includes a clock frequency generator configured to generate a redistribution clock signal with a first redistribution clock frequency during a first time period and with a second different redistribution clock frequency during a second time period. The magnetic field sensor also includes a feedback circuit path coupled at both ends to the primary circuit path and forming a feedback loop. The feedback circuit path includes a switched capacitor circuit coupled to receive the redistribution clock signal, the switched capacitor circuit forming an integrator. The switched capacitor circuit has a selectable unity gain frequency having a first unity gain frequency related to the first redistribution clock frequency during the first time period and having a second unity gain frequency related to the second redistribution clock frequency during the second time period. The feedback circuit is configured to generate an output signal coupled to control the circuit parameter.

In some embodiments of the magnetic field sensor, the clock frequency generator is further configured to generate a sample clock signal with a sample clock frequency during the first and second time periods. In these embodiments, the switched capacitor circuit is coupled to receive the sample clock signal, and the switched capacitor circuit further comprises a notch characteristic, the notch characteristic having a notch frequency related to the redistribution clock frequency.

In accordance with another aspect of the present invention, a method of adjusting a rate of a calibration or a rate of a self-test of a magnetic field sensor includes generating, with a magnetic field sensing element, a magnetic field signal in response to a magnetic field. The method also includes receiving and processing the magnetic field signal with a primary circuit path comprising a circuit parameter. The method also includes generating a redistribution clock signal with a first redistribution clock frequency during a first time period and a with a second different redistribution clock frequency during a second time period. The method also includes generating an output signal coupled to control the circuit parameter with a feedback circuit path coupled at both ends to the primary circuit path and forming a feedback loop. The feedback circuit path includes a switched capacitor circuit coupled to receive the redistribution clock signal, the switched capacitor circuit forming an integrator. The switched capacitor circuit has a selectable unity gain frequency with a first unity gain frequency related to the first redistribution clock frequency during the first time period and with a second unity gain frequency related to the second redistribution clock frequency during the second time period.

In some embodiments of the method, the method also includes generating a sample clock signal with a sample clock frequency during the first and second time periods. In these embodiments, the switched capacitor circuit is coupled to receive the sample clock signal, and the switched capacitor circuit further comprises a notch characteristic, the notch characteristic having a notch frequency related to the redistribution clock frequency.

The foregoing features of the invention, as well as the invention itself may be more fully understood from the following detailed description of the drawings, in which:

FIG. 1 is a block diagram of a prior art magnetic field sensor, that has a chopped (or switched) Hall effect element, and an associated switching circuit;

FIG. 1A is a series of graphs showing frequency spectrums at various points in the prior at magnetic field sensor of FIG. 1;

FIG. 2 is a block diagram showing a switched Hall element having a Hall effect element and having a switching circuit that can be used as the Hall effect element and the switching circuit of the magnetic field sensor of FIG. 1, and also as the Hall effect element and the switching circuit of magnetic field sensors below;

FIG. 2A is a graph showing clock signals for the switched Hall element of FIG. 2;

FIG. 2B is a graph showing a modulated offset component provided by the switched Hall element of FIG. 2;

FIG. 2C is a graph showing an un-modulated magnetic field signal component provided by the switched Hall element of FIG. 2;

FIG. 3 is a block diagram showing a switched Hall element having a Hall effect element and having a switching circuit that can be used as the Hall effect element and the switching circuit in the sensor of FIG. 1, and also as the Hall effect element and the switching circuit of magnetic field sensors below;

FIG. 3A is a graph showing clock signals for the switched Hall element of FIG. 3;

FIG. 3B is a graph showing an un-modulated offset component provided by the switched Hall element of FIG. 3;

FIG. 3C is a graph showing a modulated magnetic field signal component provided by the switched Hall element of FIG. 3;

FIG. 4 is a block diagram showing two Hall effect elements arranged in parallel in a measured-field-sensing configuration, which would tend to respond in cooperation in the presence of an external magnetic field;

FIG. 5 is a block diagram showing the two Hall effect elements of FIG. 4, reconnected so as to be in a reference-field-sensing configuration, and in the presence of the external magnetic field of FIG. 4 and also in the presence of a two reference magnetic fields as may be generated in two opposite directions, e.g., by two respective coils;

FIG. 5A is a block diagram showing the two Hall effect elements of FIG. 4, reconnected so as to be in the reference-field-sensing configuration, and in the presence of the external magnetic field of FIG. 5, and also in the presence of a two reference magnetic fields as may be generated in two opposite directions, e.g., by two respective coils, wherein the two reference magnetic fields are AC magnetic fields;

FIG. 6 is a block diagram showing two Hall elements for which couplings are alternated back and forth between the measured-field-sensing configuration and the reference-field-sensing configuration in two phases, and without chopping of the two Hall elements when in the measured-field-sensing configuration;

FIG. 7 is a block diagram showing two Hall elements for which couplings are alternated back and forth between two measured-field-sensing configurations and the reference-field-sensing configuration in four phases, wherein the two Hall elements are chopped to achieve two measured-field-sensing configurations;

FIG. 8 is a graph showing output signals from the two Hall elements of FIG. 7 and showing the signals during all of the four phases;

FIG. 9 is a graph showing output signals from the two Hall elements of FIG. 7 showing signals only during the first and third phases corresponding to measured-field-sensing configurations of the two Hall elements;

FIG. 10 is a graph showing output signals from the two Hall elements of FIG. 7 showing signals only during the second and fourth phases corresponding to the reference-field-sensing configuration of the two Hall elements;

FIG. 11 is a block diagram showing two Hall elements for which couplings are alternated back and forth between four measured-field-sensing configurations and the reference-field-sensing configuration in eight phases, wherein the two Hall elements are chopped to achieve the four measured-field-sensing configurations;

FIG. 12 is a block diagram showing a magnetic field sensor having two Hall elements, a corresponding two reference field conductors, here shown to be coils, and having two electronic channels, a first channel configured to generate an output signal responsive to a measured (normal) magnetic field, and a second channel configured to generate an output signal responsive to the reference magnetic field as generated by the two reference field conductors;

FIG. 13 is a block diagram showing a portion of the magnetic field sensor of FIG. 12, and, in particular, showing the first channel and not showing the second channel of FIG. 12;

FIGS. 14-18 are graphs showing frequency spectra at various points of the magnetic field sensor portion of FIG. 13;

FIG. 19 is a block diagram showing another portion of the magnetic field sensor of FIG. 12, and, in particular, showing the second channel and not showing the first channel of FIG. 12; and

FIGS. 20-24 are graphs showing frequency spectra at various points of the magnetic field sensor portion of FIG. 19;

FIG. 25 is a block diagram of another magnetic field sensor having two Hall elements, a corresponding two reference field conductors, here shown to be coils, also having two electronic channels, a primary circuit channel configured to generate an output signal responsive to a measured (normal) magnetic field, and a feedback circuit channel configured to both generate an output signal responsive to the reference magnetic field as generated by the two reference field conductors and also to self-calibrate (or self-test) a sensitivity of the magnetic field sensor, the feedback circuit channel having a switched capacitor circuit, the feedback circuit channel part of a feedback loop;

FIG. 26 is a block diagram of a switched capacitor circuit that can be used as the switched capacitor circuit of FIG. 25;

FIG. 27 is a block diagram of a feedback loop having two circuit elements, which is representative of the feedback loop of FIG. 25;

FIG. 28 is a graph showing a transfer function of one of the circuit elements of FIG. 27;

FIG. 29 is a graph showing a transfer function of the other one of the circuit elements of FIG. 27;

FIG. 30 is a graph showing a combination of the transfer functions of the two circuit elements of FIG. 25, therefore a loop gain of the feedback loops of FIGS. 25 and 27;

FIG. 31 is a graph showing another combination of the transfer functions of the two circuit elements of FIG. 25, therefore another loop gain of the feedback loops of FIGS. 25 and 27; and

FIG. 32 is a block diagram of another magnetic field sensor having two Hall elements, a corresponding two reference field conductors, here shown to be coils, also having two electronic channels, a primary circuit channel configured to generate an output signal responsive to a measured (normal) magnetic field, and a feedback circuit channel configured to both generate an output signal indicative of an offset of the magnetic field sensor and also to self-calibrate (or self-test) an offset voltage of the magnetic field sensor, the feedback circuit channel having a switched capacitor circuit, the feedback circuit channel part of a feedback loop.

Before describing the present invention, some introductory concepts and terminology are explained. As used herein, the term “magnetic field sensing element” is used to describe a variety of types of electronic elements that can sense a magnetic field. The magnetic field sensing elements can be, but are not limited to, Hall effect elements, magnetoresistance elements, or magnetotransistors. As is known, there are different types of Hall effect elements, for example, planar Hall elements, vertical Hall elements, and circular Hall elements. As is also known, there are different types of magnetoresistance elements, for example, anisotropic magnetoresistance (AMR) elements, giant magnetoresistance (GMR) elements, tunneling magnetoresistance (TMR) elements, Indium antimonide (InSb) elements, and magnetic tunnel junction (MTJ) elements.

As is known, some of the above-described magnetic field sensing elements tends to have an axis of maximum sensitivity parallel to a substrate that supports the magnetic field sensing element, and others of the above-described magnetic field sensing elements tend to have an axis of maximum sensitivity perpendicular to a substrate that supports the magnetic field sensing element. In particular, most, but not all, types of magnetoresistance elements tend to have axes of maximum sensitivity parallel to the substrate and most, but not all, types of Hall elements tend to have axes of sensitivity perpendicular to a substrate.

As used herein, the term “magnetic field sensor” is used to describe a circuit that includes a magnetic field sensing element. Magnetic field sensors are used in a variety of applications, including, but not limited to, a current sensor that senses a magnetic field generated by a current carried by a current-carrying conductor, a magnetic switch (also referred to herein as a proximity detector) that senses the proximity of a ferromagnetic or magnetic object, a rotation detector that senses passing ferromagnetic articles, for example, gear teeth, and a magnetic field sensor (e.g., a linear magnetic field sensor) that senses a magnetic field density of a magnetic field. Linear magnetic field sensors are used as examples herein. However, the circuits and techniques described herein apply also to any magnetic field sensor capable of detecting a magnetic field.

As used herein, the term “magnetic field signal” is used to describe any circuit signal that results from a magnetic field experienced by a magnetic field sensing element.

Reference-field-sensing configuration modes of operation described below can be used to adjust (i.e., self-calibrate) a sensitivity and/or offset voltage of a magnetic field sensor. However, the reference-field-sensing configuration can also be used to provide a self-test of the magnetic field sensor. Namely, if no output signal is generated during a reference field mode of operation (or, in the case of a linear magnetic field sensor, the output signal is too low or too high), the magnetic field sensor is deemed to have failed. Thus, as used herein, the term “reference” is used to encompass sensitivity and/or offset voltage measurement (self-test) and self-calibration.

Referring to FIG. 1, a prior art magnetic field sensor 10 includes a Hall effect element 13 coupled within a switching circuit 12. The switching circuit 12 is configured to generate a differential output signal 12a, 12b responsive to an external magnetic field. Many signals described below can be differential signals, however, the term differential is not used in all instances. In other embodiments, some or all of the signals are single ended signals.

The switching circuit 12 is more fully described below in conjunction with FIGS. 2-2C. Let it suffice here to say that the switching circuit 12 switches a drive signal (not shown) to the Hall effect element 12 with a clock at a frequency of fc.

The magnetic field sensor 10 also includes a switching circuit 14 coupled to receive the signal 12a, 12b and configured to generate a chopped signal 14a, 14b. The switching circuit 14 is also switched with the clock at a frequency of fc. Combined operation of the switching circuit 12 with the switching circuit 14 is described more fully below in conjunction with FIGS. 3-3C.

An amplifier 16 is coupled to receive the chopped signal 14a, 14b and configured to generate an amplified signal 16a, 16b. A switching circuit 18 is coupled to receive the amplified signal 16a, 16b and configured to generate a demultiplexed signal 18a, 18b. The switching circuit 18 is clocked with the clock at the frequency, fc. A low pass filter 20 is coupled to receive the demultiplexed signal 18a, 18b and configured to generate a filtered signal 20a, 20b. A sinx/x (sine) filter 22 is coupled to receive the filtered signal 20a, 20b and configured to generate a filtered signal 22a, 22b, i.e., an output signal from the magnetic field sensor 10.

In some embodiments, the sine filter 22 is a switched capacitor filter having a first notch at a frequency fc. However, in other embodiments, the sine filter 22 is generated digitally. In still other embodiments, the sine filter 22 is an analog unclocked filter.

It will be understood that clock frequency provided to the sine filter 22 can be at a frequency of fc as shown to provide the notch at the frequency fc. However, it will also be understood that the sine filter 22 can be designed to have the notch at the frequency fc but using a clock signal at a different frequency. In conjunction with figures below, the clock provided to the sine filter 22 is described to be at the frequency fc. However, it is the notch frequency at the frequency fc that is desired.

It will be understood that the magnetic field sensor output signal 22a, 22b is a linear signal proportional to a magnetic field experienced by the magnetic field sensing element 12 and that the magnetic field sensor 10 is a linear magnetic field sensor. However, in other embodiments, a comparator can receive the signal 22a, 22b, the magnetic fields sensor output signal thus generated by the comparator is a two-state signal, and the magnetic field sensor is a magnetic switch. It will also be understood that, in some embodiments, only one of the filters 20, 22 is used.

Operation of the magnetic field sensor of FIG. 1 is described below in conjunction with FIG. 1A.

Referring now to FIG. 1A, graphs 26 each include a horizontal axis having units of frequency in arbitrary units and a vertical axis having units of power in arbitrary units.

A graph 28 is representative of the signal 12a, 12b, (i.e., frequency spectra of the signal 12a, 12b) and shows an external magnetic field signal, Bexternal, plus a residual offset signal, ResOff, appearing at a frequency, which can be a zero frequency indicative of a DC external magnetic field. A Hall effect offset signal, HallOff, is at a different frequency, according to a frequency of the clock, fc. This effect is further described in conjunction with FIGS. 2-2C.

The Hall effect offset signal, HallOff, corresponds to a DC voltage error that would be present in the output signal 12a, 12b of the Hall effect element 13, but when the switching circuit 12 is not switching, i.e., when the current through the Hall effect elements 104, 106 is directed in one particular respective direction. As shown in the graph 28, the Hall effect offset signal, HallOff, is shifted to a higher frequency in the differential signal 12a, 12b by switching operation of the switching circuit 12 (and is shifted back to DC by operation of the switch circuit 14, as described below in conjunction with graph 30). The residual offset signal, ResOff, corresponds to a remaining offset signal that remains at DC in the differential signal 12a, 12b even when the switching circuit 12 is switching (and is shifted to a higher frequency by operation of the switching circuit 14, as described below in conjunction with graph 30).

A graph 30 is representative of the signal 14a, 14b, after chopping. The Hall offset signal, HallOff, is shifted to DC by operation of the switching circuit 14, and the signal Bexternal+ResOff is at the frequency fc.

A graph 32 is representative of the signal 16a, 16b. In the graph 32, a DC offset of the amplifier 16 is added to the Hall offset signal at DC resulting in a signal HallOff+AmpOff at DC.

A graph 34 is representative of the signal 18a, 18b, after the switching circuit 18. As can be seen, the signal Bexternal+ResOff is now at DC and the signal HallOff+AmpOff is now at the frequency, fc.

A graph 36 is representative of the signals 20a, 20b after the filter 20. A break frequency of the filter 20 is selected to be below the frequency, fc. The signal HallOff+AmpOff is reduced, as is desired.

A graph 38 is representative of the signal 22a, 22b, after the sinc filter 22. The notch of the sinc filter 22 is selected to be at the frequency, fc, i.e., at a Nyquist frequency of the sinc filter 22. Only the external magnetic field signal (plus some residual offset) remains in the graph 38 and in the signal 22a, 22b. The Hall effect element offset (HallOff) has been removed.

Referring now to FIGS. 2-2C, a switched Hall element 50 of a type that modulates a Hall offset component (e.g., 58) includes a Hall element (or Hall plate) 52 and a modulation circuit 54. The Hall element 52 includes four contacts 52a, 52b, 52c, and 52d, each coupled to a first terminal of a respective switch 56a, 56b, 56c, and 56d, as shown. Second terminals of switches 56b and 56c are coupled to provide a positive node of a switched Hall output signal, here labeled Vo+, and second terminals of switches 56a and 56d are coupled to provide a negative node of the switched Hall output signal, here labeled Vo−.

Additional switches 60a, 60b, 60c, and 60d are arranged to selectively couple the Hall contacts 52a, 52b, 52c, 52d to the supply voltage, Vs, and ground. More particularly, switches 56b, 56d, 60a, and 60c are controlled by a clock signal, CLK, and switches 56a, 56c, 60b, and 60d are controlled by a complementary clock signal, CLK/, as shown. The clock signals CLK and CLK/ have two states or phases, a Φ state and a Φ90° state, as shown in FIG. 2A.

In operation, during phase Φ current flows from the terminal 52a to the terminal 52c and the switched Hall output signal, Vo, is equal to VH+Vop, where Vop is the Hall element offset voltage or Hall offset component and VH is the magnetic field signal component. During the phase Φ90°, current flows from the terminal 52b to the terminal 52d and the switched Hall output signal, Vo, is equal to VH−Vop. Thus, the modulation circuit 54 modulates the Hall offset component, Vop, which is shown in FIG. 2B. The magnetic field signal component, VH, remains substantially invariant, as shown in FIG. 2C.

The chopping circuit 70 of FIG. 3 can be used as the combined switching circuits 12, 14 of FIG. 1.

Referring now to FIGS. 3-3C, an alternative switched Hall element 70 of a type that modulates a magnetic field signal component (which can be used for the switching circuits 12, 14 of FIG. 1) includes a Hall element 72 and a modulation circuit 74. The Hall effect element 72 is the same as the Hall effect element 52 of FIG. 2 and includes four contacts 72a, 72b, 72c, and 72d, each coupled to a first terminal of a respective switch 76a, 76b, 76c, and 76d. Second terminals of switches 76a and 76b are coupled to provide a positive node of a switched Hall output signal, here labeled Vo+, and second terminals of switches 56c and 56d are coupled to provide a negative node of the switched Hall output signal, here labeled Vo−. Thus, a comparison of FIGS. 2 and 3 reveals that the output contacts of the Hall element are interchanged during the Φ90° phase.

Additional switches 80a, 80b, 80c, and 80d are arranged to selectively couple the Hall contacts 72a, 72b, 72c, and 72d to the supply voltage Vs and ground. Switches 76b, 76d, 80a, and 80c are controlled by clock signal, CLK, and switches 76a, 76c, 80b, and 80d are controlled by a complementary clock signal, CLK/, as shown. Clock signals, CLK and CLK/, are identical to like signals in FIG. 2 and thus have two states or phases, Φ and Φ90°, as shown.

In operation, during phase Φ, current flows from the terminal 72a to the terminal 72c, and the switched Hall output signal, Vo, is equal to VH+Vop. During phase Φ90°, current flows from the terminal 72b to the terminal 72d, and the switched Hall output signal, Vo, is equal to −VH+Vop. Thus, the modulation circuit 74 modulates the magnetic signal component to provide a modulated magnetic signal component, VH, which is shown in FIG. 3C. The offset component, Vop, remains substantially invariant as is shown in FIG. 3B.

It will be understood that the switches 80a-80d can form a switching circuit the same as or similar to the switching circuit 12 of FIG. 1. It will also be understood that the switches 76a-76d can form a switching circuit the same as or similar to the switching circuit 14 of FIG. 1

In some embodiments, the combination of the switching circuit 12 and the switching circuit 14 of FIG. 1 is of a type described above in conjunction with FIGS. 3-3C, rather than of a type described above in conjunction with FIGS. 2-2C.

Referring now to FIG. 4, two Hall effect elements can be coupled together in parallel. The two Hall effect elements coupled in parallel can be used in place of any of the single Hall effect elements described above in conjunction with FIGS. 1-3C. Thus, the output (plus and minus) of the two parallel Hall effect elements can be used in place of a plus and minus output from one Hall effect element. Drive signals (not shown in FIG. 4) can drive the two parallel Hall effect elements just as they drive the one Hall effect element in any of the above figures.

The parallel arrangement of Hall effect elements is referred to herein as a measured-field-sensing configuration, as opposed to a reference-field-sensing configuration described more fully below.

Referring now to FIG. 5, the two Hall effect elements of FIG. 4 can be coupled together (i.e., re-connected) in a reference-field-sensing configuration. With this arrangement, it should be understood that the combination of the two Hall effect elements is substantially unresponsive to an external magnetic field, Bexternal, in the same direction as experienced by each one of the two Hall effect elements. A residual response to the external magnetic field can be due to a mismatch of the two Hall effect elements, which would result in a residual external magnetic field signal.

However, it will also be understood that, in response to two reference magnetic fields, Bcoil, in different directions as experienced by each one of the two Hall effect elements arranged in the reference-field-sensing configuration, the combination of the two magnetic field sensing elements does generate a non-zero output signal, VBcoil.

Referring now to FIG. 5A, the two Hall effect elements are again shown arranged in the reference-field-sensing configuration. Here, two phases (directions) of each of the two reference magnetic fields, Bcoil, are shown. In essence, in response to an AC reference magnetic field, the output signal, VBcoil, is an AC signal. However, when the two Hall effect elements are arranged in the reference-field-sensing configuration, the output signal has substantially zero contribution from the external magnetic field, which is in the same direction at both Hall effect elements, regardless of whether the external magnetic field is a DC magnetic field or an AC magnetic field.

Referring now to FIG. 6, two magnetic field sensing elements, which are the same two magnetic field sensing elements, are shown in two different phase arrangements. The two different phase arrangements are achieved alternately by way of a switching circuit described more fully below in conjunction with FIG. 12.

As used herein, the word “phase” is used in many instances to describe both a coupling arrangement of two or more magnetic field sensing elements into the measured-field-sensing configuration or into the reference-field-sensing configuration and also a direction of a current passing through a reference field conductor, which is shown here to be a simple conductor, but which, in other arrangements described below, for example, in FIG. 12, can be comprised of two reference field coil portions. The word phase as used herein does not refer to a chopping arrangement, described more fully below.

Referring first to a phase 1 arrangement, the two magnetic field sensing elements are coupled in the measured-field-sensing configuration, which is the same as or similar to the coupling arrangement described above in conjunction with FIG. 4. As described above, with this coupling arrangement, the two magnetic field sensing elements are responsive to an external magnetic field as may be received from the environment and collectively generate a so-called “measured-magnetic-field-responsive signal.”

A reference field conductor is shown as dashed line, the dashed line indicative of no current being carried by the reference field conductor. However, in an alternate embodiment, the reference field conductor can carry a current, IREF.

It will be recognized that a current carried by the reference field conductor generates a magnetic field around the reference field conductor. It will also be recognized that, due to the path of the reference field conductor, the magnetic field has a direction into the page at the right-hand magnetic field sensing element and out of the page at the left-hand magnetic field sensing element. Thus, two magnetic fields generated by the reference field conductor are in opposite directions at the two magnetic field sensing elements. Because the two magnetic field sensing elements are coupled in parallel in the measured-field-sensing configuration and both have the same direction of response, the output signal generated by the two magnetic field sensing elements in response to a current carried by the reference field conductor will be zero or near zero.

Thus, any current passing through the reference field conductor has little or no effect on an output signal generated collectively by the two magnetic field sensing elements when coupled in the measured-field-sensing configuration.

In contrast, in response to a measured magnetic field, as may be received from the environment, which passes through both of the Hall elements in the same direction, the measured-magnetic-field-responsive signal is not zero. Thus, when coupled in the phase 1 arrangement, the two magnetic field sensing elements are not responsive to a magnetic field generated by the reference field conductor, but are responsive to a measured (external of normal) magnetic field.

In a phase 2 arrangement, the two magnetic field sensing elements are coupled in the reference-field-sensing configuration, which is the same as or similar to the coupling arrangement described above in conjunction with FIGS. 5 and 5A. From discussion above, it will be understood that, when in the reference-field-sensing configuration, the two magnetic field sensing elements are responsive in opposite directions to magnetic fields perpendicular to the page.

In the phase 2 arrangement of the two magnetic field sensing elements, the reference field conductor, which is the same reference field conductor shown in this phase 1 arrangement, carries a current, IREF. As described above in the phase 1 arrangement, the current, IREF, generates magnetic fields at the two magnetic field sensing elements that are in opposite directions. Because the two magnetic field sensing elements in the reference-field-sensing configuration have opposite sensitivities to magnetic fields, in the presence of the current, IREF, a non-zero output signal, referred to herein as a “reference-magnetic-field-responsive signal” is generated by the two magnetic field sensing elements. Thus, when coupled in the phase 2 arrangement, the two magnetic field sensing elements are responsive to a magnetic field generated by the reference field conductor, but are not responsive to a measured (external or normal) magnetic field

It will become apparent from discussion below that a magnetic field sensor can operate by alternating back and forth between the phase 1 and phase 2 arrangements. It should be apparent that, with this alternating arrangement, the measured-field-sensing configuration is always the same, and thus, there is no chopping of the two Hall elements. Chopping in the measured-field-sensing configuration is described more fully below in conjunction with FIGS. 7 and 10.

Taken together, since they are from the same two magnetic field sensing elements but taken at different times, the measured-magnetic-field-responsive signal and the reference-magnetic-field-responsive signal are referred to herein simply as a “magnetic field signal,” which is responsive to magnetic fields

From figures below it will become apparent that because couplings of the two magnetic field sensing elements, for example the two magnetic field sensing elements of FIG. 6, are alternated back and forth, the magnetic field signal has both the measured-magnetic-field-responsive signal portions responsive to a measured magnetic field when coupled in the measured-field-sensing configuration and a reference-magnetic-field-responsive signal portions responsive to a reference magnetic field when coupled in the reference-field-sensing configuration. As further described below, because the measured-field-sensing configuration and the reference-field-sensing configuration occur alternately back-and-forth, by using time division multiplexing, the measured-magnetic-field-responsive signal portions can be separated from the reference-magnetic-field-responsive signal portions in ways described more fully below.

Referring now to FIG. 7, two magnetic field sensing elements, which are the same two magnetic field sensing elements, are shown in four different phase arrangements, two in the measured-field-sensing configuration and two in the reference-field-sensing configuration (a 2× chopping arrangement associated with each configuration). The four different phase arrangements are achieved sequentially and repetitively by way of a switching circuit described more fully below in conjunction with FIG. 12.

Referring first to a phase 1 arrangement, the two magnetic field sensing elements are coupled in the measured-field-sensing configuration, which is the same as or similar to the measured-field-sensing-configuration coupling arrangement described above in conjunction with FIG. 4. As described above, with this coupling arrangement, the two magnetic field sensing elements are responsive to an external magnetic field as may be received from the environment and collectively generate the measured-magnetic-field-responsive signal, responsive to a measured (external) magnetic field.

A reference field conductor is shown as dashed line, the dashed line indicative of no current being carried by the reference field conductor. However, in an alternate embodiment, the reference field conductor can carry a current.

In a phase 2 arrangement, the two magnetic field sensing elements are coupled in the reference-field-sensing configuration, which is the same as or similar to the reference field coupling arrangement described above in conjunction with FIGS. 5 and 5A. From discussion above, it will be understood that the two magnetic field sensing elements are coupled in way such that the two magnetic field sensing elements are responsive in opposite directions to a magnetic field perpendicular to the page.

In the phase 2 arrangement of the two magnetic field sensing elements, the reference field conductor, which is the same reference field conductor shown in this phase 1 arrangement, carries a current, IREF. The current, IREF, generates magnetic fields at the two magnetic field sensing elements that are in opposite directions. Because the two magnetic field sensing elements in the reference-field-sensing configuration have opposite sensitivities to a magnetic field, in the presence of the current, IREF, a non-zero output signal, the reference-magnetic-field-responsive signal, is generated by the two magnetic field sensing elements. In the phase 2 arrangement, the two magnetic field sensing elements are responsive to the magnetic fields generated by the reference field conductor and or not responsive to the measured (external) magnetic field.

In a phase 3 arrangement, the two magnetic field sensing elements are again coupled in the measured-field-sensing configuration. However, the two magnetic field sensing elements are coupled so as to have a reverse polarity from that shown in the phase 1 arrangement. The reverse polarity is representative of the part of the above-described chopping of the two magnetic field sensing elements, described, for example, in conjunction with FIGS. 3-3C.

Different directions of arrows within the Hall elements are representative of different couplings of drive signals (not shown) to a selected two of the terminals of the individual Hall elements. Conventional Hall elements are four terminal devices, wherein two of the terminals are coupled to pass a drive current, and the remaining two terminals provide a differential output signal. It will be recognized that the four terminals can be coupled in at least four different configurations. If an individual Hall element is coupled into two or more of these different configurations and the output signals from the two or more different configurations are arithmetically processed (e.g., summed or otherwise averaged), arithmetically processed signal has less of an offset voltage than the output signal taken at any one of the different configurations. This summing or averaging of output signals associated with different configurations corresponds to the above-mentioned “chopping.”

The arrangement of FIG. 7, in particular, the two measured-field-sensing configurations of phase 1 and phase 3, is representative of a 2× chopping of the two Hall elements. Essentially, the measure-magnetic-field-responsive signal portions, which occur at different times, can be arithmetically processed to reduce an offset voltage.

In the phase 3 arrangement of the two magnetic field sensing elements, the reference field conductor, which is the same reference field conductor shown in the phase 1 and phase 2 arrangements, carries no current. However, in an alternate embodiment, the reference field conductor can carry a current. The same as for the phase 1 arrangement, in the phase 3 arrangement, the two magnetic field sensing elements taken collectively are again not responsive to the magnetic field is generated by a current carried by a reference field conductor, but are responsive to an external magnetic field.

In a phase 4 arrangement, the two magnetic field sensing elements are again coupled in the reference-field-sensing configuration.

In the phase 4 arrangement of the two magnetic field sensing elements, the reference field conductor, which is again the same reference field conductor shown in the phase 1, phase 2, and phase 3 arrangements, carries the current, I REF, but in the opposite direction from that which is shown in the phase 2 arrangements. The same as for the phase 2 arrangement, in the phase 4 arrangement, the two magnetic field sensitive elements taken together are responsive to the magnetic fields generated by the current, IREF, and not responsive to an external magnetic field.

Taken together, since they are from the same two magnetic field sensing elements, the measured-magnetic-field-responsive signal and the reference-magnetic-field-responsive signal are referred to herein simply as a “magnetic field signal,” which is responsive to magnetic fields

From figures below it will become apparent that because couplings of the two magnetic field sensing elements, for example the two magnetic field sensing elements of FIG. 7, are alternated back and forth, the magnetic field signal has both the measured-magnetic-field-responsive signal portions responsive to a measured magnetic field when coupled in the measured-field-sensing configuration and a reference-magnetic-field-responsive signal portions responsive to a reference magnetic field when coupled in the reference-field-sensing configuration. Because the measured-field-sensing configuration and the reference-field-sensing configuration occur alternately back-and-forth, by using time division multiplexing, the measured-magnetic-field-responsive signal portion can be separated from the reference-magnetic-field-responsive signal portion in ways described more fully below.

Referring now to FIG. 8, the graph 100 includes a horizontal axis with a scale in arbitrary units of time and of vertical axis with a scale in arbitrary units of voltage. A magnetic field signal 102 is representative of a magnetic field signal as may be generated, for example, by the two magnetic field sensing elements described above in conjunction with FIG. 7 during the four phases.

The graph 100 shows four time periods t0-t1, t1-t2, t2-t3, t3-t4. Each one of the time periods t0-t1, t1-t2, t2-t3, t3-t4 corresponds to a respective one of phase 1, phase 2, phase 3, and phase 4 of FIG. 7. The magnetic field signal 102 includes a measured-magnetic-field-responsive signal portion 102a, a reference-magnetic-field-responsive signal portion 102b, a measured-magnetic-field-responsive signal portion 102c, and a reference-magnetic-field-responsive signal portion 102d as may be generated by the two magnetic field sensing elements of FIG. 7 as the two magnetic field sensing elements are sequenced through the four phases, phase 1, phase 2, phase 3, and phase 4.

The two measured-magnetic-field-responsive signal portions 102a, 102c have magnitudes representative of a magnitude of an external magnetic field as may be sensed by the two magnetic field sensing elements, first with a magnitude in one direction in phase 1 and then in the other direction in phase 3 due to the different coupling of drive signals.

The two reference-magnetic-field-responsive signal portions 102b, 102d have magnitudes representative of a magnitude of the reference magnetic field (having two reference magnetic field portions in opposite directions) as may be generated by the current, IREF, passing through the reference field conductor of FIG. 6, first in one direction in phase 2 and then in the other direction in phase 4.

The magnetic field signal 102 has an offset voltage 104. Thus, the two measured-magnetic-field-responsive signal portions 102a, 102c have magnitudes centered about the offset voltage 104. Similarly, the two reference-magnetic-field-responsive signal portions 102b, 102d have magnitudes centered about the offset voltage 104.

It should be understood that the offset voltage 104 is not desirable. By techniques described more fully below, the offset voltage 104 can be removed.

Referring now to FIG. 9, in which like elements of FIG. 8 are shown having like reference designations, a graph 120 has the same horizontal axis and the same vertical axis as those shown in conjunction with FIG. 8. Here however, only the two measured-magnetic-field-responsive signal portions 102a, 102c are shown as could be separated out from the magnetic field signal 102 of FIG. 8 by way of time division multiplexing.

Referring now to FIG. 10, in which like elements of FIG. 8 are shown having like reference designations, a graph 140 has the same horizontal axis and the same vertical axis as those shown in conjunction with FIG. 8. Here however, only the two reference-magnetic-field-responsive signal portions 102b, 102d are shown as could be separated out from the magnetic field signal 102 of FIG. 8 by way of time division multiplexing.

Referring now to FIG. 11, two magnetic field sensing elements are again shown but here with eight different phases, i.e., couplings of the magnetic field sensing elements and directions of current through a conductor. As with the arrangements of FIGS. 6 and 7, phases phase 1, phase2, phase3, phase4, phase5, phase6, phase7, phase8 alternate back and forth between having the magnetic field sensing elements coupled in the measured-field-sensing configuration (i.e., during measurement time periods) and in the reference-field-sensing configuration (i.e., during reference time periods) (a 4× chopping arrangement associated with each configuration). Here it is shown that the current alternates in direction upon every other phase of the two magnetic field sensing elements.

Again, when in the measured-field-sensing configurations of phase 1, phase 3, phase 5, and phase 7, current through the conductor can be turned off, which is represented by dashed lines.

Measured-field-sensing configurations of phase 1, phase 3, phase 5, phase 7 each have a different couplings (.e., four different couplings) of drive signals (not shown) as represented by different directions of arrows within the two magnetic field sensing elements. In accordance with the four different couplings, it will be recognized that the arrangement shown FIG. 11 is a 4× chopping arrangement and output signals from these four different phases can be summed or otherwise averaged in order to achieve a reduced offset voltage when in the measured-field-sensing configurations.

Referring now to FIG. 12, a magnetic field sensor 200 includes two reference field conductors 206a, 206b here shown the form of conductive reference field coils, each reference field coil wound in an opposite direction from the other so as to generate, in response to the current flowing through the two reference field coils, magnetic fields in opposite directions. The two reference field conductors 206a, 206b are coupled in series and coupled to receive a current 202 by way of a switching circuit 204. In response to a control signal 204a, the switching circuit 204 is operable to periodically reverse a direction of the current 202 passing through the two reference field conductors 206a, 206b.

The magnetic field sensor 200 also includes two magnetic field sensing elements 208, 210, here shown in the form of two Hall elements. The two magnetic field sensing elements 206, 208 are coupled in a switching circuit 212. While two Hall elements 208, 210 are shown, in other embodiments, similar circuits and functionality could be achieved with two or more magnetoresistance elements,

In response to a control signal 212a, the switching circuit 212 is operable to couple the two magnetic field sensing elements 208, 210 back and forth into the measured-field-sensing configuration and into the reference-field-sensing configuration shown above in conjunction with FIGS. 6, 7, and 11. The switching back and forth can have no chopping when in the measured-field-sensing-configuration as represented in FIG. 6, a 2× chopping when in the measured-field-sensing configuration as represented in FIG. 7, a 4× chopping when in the measured-field-sensing configuration as represented in FIG. 11, or other chopping arrangements.

A magnetic field signal, which can be a differential electronic magnetic field signal, is identified by reference designator A. As described above, the magnetic field signal, A, can include both a measured-magnetic-field-responsive signal portion responsive to a measured magnetic field (and not responsive to a reference magnetic field) when coupled in the measured-field-sensing configuration, and a reference-magnetic-field-responsive signal portion responsive to the reference magnetic field (and not responsive to the measured magnetic field) when coupled in the reference-field-sensing configuration. The two signal portions can occur periodically and alternately, for example, as described above in conjunction with FIG. 6, 7, or 11.

A switching circuit 214 is coupled to receive the differential signal, i.e., the magnetic field signal, A, and configured to generate a switched signal, shown to be a differential signal, identified by reference designator B. It should be understood that the switching circuit 214 in combination with the switching circuit 212 provides the full chopping of the two Hall elements 208, 210, and the switching circuits 214, 212 are comparable to the switches 80a-80d and 76a-76d, respectively, of FIG. 3. However, unlike the arrangement of FIGS. 3-3C, which shows 2× chopping, the switching circuits 212, 214 of FIG. 12 are representative of 4× chopping as shown, for example, in FIG. 11.

The switching circuit 214 is coupled to receive a control signal 214a. An amplifier 216 is coupled to receive the switched signal, B, and is configured to generate an amplified signal, shown to be at differential signal, identified by reference designator C.

In part of a first circuit channel, i.e., a measured-field-sensing channel (also referred to herein as a so-called “primary circuit path”), a switching circuit 218 is coupled to receive the differential signal, C, and configured to generate a switched signal, shown to be a differential signal, identified by reference designator D.

In a further part of the first circuit channel, a filter circuit 220 is coupled to receive the differential signal, D, and configured to generate a filtered signal received by another filter circuit 222. The filter circuit 222 can be configured to generate a signal, shown to be a differential signal, identified by reference designator, F. The signal, F, can be the above-described measured-magnetic-field-responsive signal portion.

In part of a second circuit channel, i.e., a reference-field-sensing channel, which can also provide a so-called “feedback circuit path,” a switching circuit 224 is coupled to receive the differential signal, C, and configured to generate a switched signal, shown to be a differential signal, identified by reference designator E.

In a further part of the second circuit channel, a filter circuit 226 is coupled to receive the differential signal, E, and configured to generate a filtered signal received by another filter circuit 228. The filter circuit 228 can be configured to generate an output signal, shown to be a differential signal, identified by reference designator G. The output signal G can be the above-described reference-magnetic-field-responsive signal.

The output signals F and G, i.e., the measured-magnetic-field-responsive signal portion and the reference-magnetic-field-responsive signal portion, can occur back and forth repetitively and periodically.

The magnetic field sensor 200 can also include an amplifier 219 coupled to receive the output signal, G, i.e., the reference-magnetic-field-responsive signal, coupled to receive a reference signal, VREF, and configured to generate an error signal 219a. A bias circuit can be coupled to receive the error signal 219a and configured to generate bias signals 230a, 230b, which, in some embodiments, can be current signals, configured to drive and pass through two terminals of each respective one of the two Hall elements 208, 210 by way of the switching circuit 212.

In operation, the error signal 219a controls a magnitude of the bias signals 230a. 230b. An output signal, G, that is too large relative to the reference signal, VREF, results in a reduction of the bias signals 230a, 230b. Thus, an effective gain or sensitivity of the magnetic field sensor 200 is controlled in relation to the reference voltage, VREF.

In some alternate embodiments, the error signal 219a instead controls a gain of the amplifier 216.

In some other alternate embodiments, the amplifier 219 is not used, and instead the output signal, G, is received by and used by another processor (not shown) to adjust a magnitude of a signal related to the output signal, F.

Further operation of the magnetic field sensor 200 is described below in conjunction with FIGS. 13-24. In particular, FIG. 13 shows the magnetic field sensor 200 of FIG. 12 when the two magnetic field sensing elements 208, 210 are coupled repetitively and periodically in the measured-field-sensing configuration. Similarly, FIG. 19 shows the magnetic field sensor 200 of FIG. 12 when the two magnetic field sensing elements 208, 210 are coupled repetitively and periodically, for example, in the reference-field-sensing configuration of FIG. 7.

Referring now to FIG. 13, in which like elements of FIG. 12 are shown having like reference designations, a portion 300 of the magnetic field sensor 200 of FIG. 12 but having only the first channel, which generates the measured-magnetic-field-responsive signal, F, is shown.

When the two magnetic field sensing elements 208, 210 are coupled in the measured-field-sensing configuration repetitively and periodically, the switching circuit 204 can be coupled into any configuration. Here is shown that the switching circuit 204 does not switch, meaning that the switching circuit 204 is a pass-through each time that the two magnetic field sensing elements 208, 210 are coupled into the measured-field-sensing configuration by the switching circuit 212.

Also, when in the measured-field-sensing configuration, the current 202 through the two reference field coils 206a, 206b can be set to zero. It will be understood from discussion above that, when the two magnetic field sensing elements 208, 210 are coupled in the measured-field-sensing configuration, taken together they are responsive to magnetic fields in the same direction and not to magnetic fields as would be generated in opposite directions by the two reference field coils 206a, 206b. Thus the current 202 can be set to zero in order to conserve power.

The switching circuit 214 is shown by way of the switching symbol inside of the switching circuit 214 to be switching, meaning, that upon each occurrence of the measured-field-sensing configuration coupling of the two magnetic field sensing elements 208, 210 by the switching circuit 212, the switching circuit 214 reverses couplings between the two magnetic field sensing elements 208, 210 and the amplifier 216. This results in a frequency shift of components of the magnetic fields signal, A, as further described below.

The switching circuit 218 is also shown by way of the switching symbol inside of the switching circuit 218 to be switching, again meaning, that upon each occurrence of the measured-magnetic-field-configuration couplings of the two magnetic field sensing elements 208, 210 by the switching circuit 212, the switching circuit 218 reverses couplings between amplifier 216 and the filter circuit 220. This also results in another frequency shift of components of the amplified signal, C, as further described below.

As indicated, the control signals 214a, 218a switch the respective switching circuits 214, 218 with a switching rate of fck. In contrast, the switching circuit 212 switches with the switching rate of 2fck, meaning that the switching circuit 212 achieves the measured-field-sensing configuration of the two magnetic field sensing elements 208, 210 on every other clock cycle of the control signal 212a.

FIGS. 14-18 show frequency domain graphs of the signals, A, B, C, D, and F, that occur within the portion 300 of the magnetic field sensor 200 with the two magnetic field sensing elements 208, 210 coupled repetitively and periodically in the normal configuration mode of operation. In particular, FIGS. 14-18 are representative of the 4× chopping of FIG. 11 for the measured-field-sensing configuration mode of operation.

Referring now to FIG. 14, a graph 320 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 320 includes three spectral lines when in the presence of a stationary, i.e. non-varying, magnetic field. The magnetic field is a sensed or external magnetic field.

The graph 320 is representative of the magnetic field signal, A, associated with the magnetic field sensor portion 300 of FIG. 13, i.e. the magnetic field signal, A, taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the measured-field-sensing configuration.

A first spectral line (left) occurs at DC and has a magnitude corresponding to a magnitude, Bext, of the external, or sensed, magnetic field plus an undesirable residual offset voltage (after chopping) generated by the two magnetic field sensing elements 208, 210 of FIG. 13.

A second spectral line occurs at a frequency of fck/2 and results from the 4× chopping described above.

A third spectral line occurs at a frequency of fck and also results from the 4× chopping described above. Essentially, the 4× chopping can be considered as two 2× choppings one right after the other, and thus, the spectral line at the frequency of fck is like that which would occur if 2× chopping were used.

Referring now to FIG. 15, a graph 330 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 330 includes three spectral lines when in the presence of a stationary, i.e. non-varying, magnetic field. The magnetic field is a sensed or external magnetic field.

The graph 330 is representative of the magnetic field signal, B, associated with the magnetic field sensor portion 300 of FIG. 13 taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the measured-field-sensing configuration.

As can be seen, by operation of the switching circuit 214 of FIGS. 12 and 13, frequencies have been shifted.

A first spectral line (left) occurs at DC and has a magnitude related to the magnitude of the third spectral line of FIG. 14.

A second spectral line occurs at a frequency of fck/2 and has a magnitude related to the magnitude of the second spectral line of FIG. 14.

A third spectral line occurs at a frequency of fck and has a magnitude related to the magnitude of the first spectral line of FIG. 14, corresponding to the magnitude, Bext, of the external, or sensed, magnetic field plus the undesirable residual offset voltage (after chopping) generated by the two magnetic field sensing elements 208, 210 of FIG. 13.

Referring now to FIG. 16, a graph 340 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 340 includes three spectral lines when in the presence of a stationary, i.e. non-varying, magnetic field. The magnetic field is a sensed or external magnetic field.

The graph 340 is representative of the magnetic field signal, C, associated with the magnetic field sensor portion 300 of FIG. 13 taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the measured-field-sensing configuration.

As can be seen, the amplifier 216 adds an offset component, AmpOff, to the first spectral line of FIG. 15 appearing at DC. Otherwise, the three spectral lines of FIG. 16 are the same as those of FIG. 15, but scaled according to a gain of the amplifier 216.

Referring now to FIG. 17, a graph 350 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 350 includes three spectral lines when in the presence of a stationary, i.e. non-varying, magnetic field. The magnetic field is a sensed or external magnetic field.

The graph 350 is representative of the magnetic field signal, D, associated with the magnetic field sensor portion 300 of FIG. 13 taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the measured-field-sensing configuration.

As can be seen, by operation of the switching circuit 218 of FIGS. 12 and 13, frequencies have been shifted.

A first spectral line (left) occurs at DC and has a magnitude related to the magnitude of the third spectral line of FIG. 16, corresponding to the magnitude, Bext, of the external, or sensed, magnetic field plus the undesirable residual offset voltage (after chopping) generated by the two magnetic field sensing elements 208, 210 of FIG. 13.

A second spectral line occurs at a frequency of fck/2 and has a magnitude related to the magnitude of the second spectral line of FIG. 16.

A third spectral line occurs at a frequency of fck and has a magnitude related to the magnitude of the first spectral line of FIG. 16.

Referring now to FIG. 18, a graph 360 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 360 includes one spectral line when in the presence of a stationary, i.e. non-varying, magnetic field. The magnetic field is a sensed or external magnetic field.

The graph 360 is representative of the magnetic field signal, F, associated with the magnetic field sensor portion 300 of FIG. 13 taken when the two magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the measured-field-sensing configuration.

As can be seen, by operation of the filter circuits 220, 222 of FIGS. 12 and 13, some spectral components of FIG. 17 have been removed, leaving only the a spectral line at DC having a magnitude corresponding to the magnitude, Bext, of the external, or sensed, magnetic field plus the undesirable residual offset voltage, ResOff, (after chopping) generated by the two magnetic field sensing elements 208, 210 of FIG. 13. The spectral line of FIG. 18 is representative of the above-described measured-magnetic-field-responsive signal.

Referring now to FIG. 19, in which like elements of FIG. 12 are shown having like reference designations, a portion 400 of the magnetic field sensor 200 of FIG. 12 but having only the second channel, which generates the reference-magnetic-field-responsive signal, G, includes elements shown.

When the two magnetic field sensing elements 208, 210 are coupled in the reference-field-sensing configuration repetitively and periodically, the switching circuit 204 switches to reverse a direction of the current 202 each time that the two magnetic field sensing elements 208, 210 are coupled into the reference-field-sensing configuration by the switching circuit 212.

When in the reference-field-sensing configuration, the current 202 through the two reference field coils 206a, 206b can be set to the value of IREF. It will be understood from discussion above that when the two magnetic field sensing elements 208, 210 coupled in the reference-field-sensing configuration, taken together they are responsive to magnetic fields in opposite directions as would be generated in opposite directions by the two reference field coils 206a, 206b, and not to a magnetic field in the same direction as would be an external or sensed magnetic field.

The switching circuit 214 is shown to not be switching, meaning, that upon each occurrence of the reference-field-sensing configuration coupling of the two magnetic field sensing elements 208, 210 by the switching circuit 212, the switching circuit 214 merely passes the magnetic field signal, A, to the amplifier 216 as the signal, B, without switching, This results in no frequency shift of components of the magnetic fields signal, A, further described below.

In contrast, the switching circuit 224 is shown by way of the switching symbol inside of the switching circuit 224 to be switching, meaning, that upon each occurrence of the reference-field-sensing configuration couplings of the two magnetic field sensing elements 208, 210 by the switching circuit 212, the switching circuit 218 reverses couplings between amplifier 216 and the filter circuit 226. This results in a frequency shift of components of the amplified signal, C, as further described below.

As indicated, the control signals 204a, 224a switch the respective switching circuits 204, 224 with a switching rate of fck. In contrast, the switching circuit 212 switches with the switching rate of 2fck, meaning that the switching circuit 212 achieves the reference-field-sensing configuration of the two magnetic field sensing elements 208, 210 on every other clock cycle of the control signal 212a, and the measured-field-sensing configuration on other ones of the clock cycles.

FIGS. 20-24 show frequency domain graphs of the signals, A, B, C, E, and G, that occur within the portion 400 of the magnetic field sensor 200 with the two magnetic field sensing elements 208, 210 coupled repetitively and periodically in the reference-field-sensing configuration mode of operation. In particular, FIGS. 20-24 are representative of the 4× chopping of FIG. 11 for the reference-field-sensing configuration mode of operation.

Referring now to FIG. 20, a graph 420 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 420 includes two spectral lines when in the presence of a periodically reversing reference magnetic field generated by the periodic reversal of the current 202 by operation of the switching circuit 204.

The graph 420 is representative of the magnetic field signal, A, associated with the magnetic field sensor portion 400 of FIG. 19, i.e. the magnetic field signal, A, taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the reference-field-sensing configuration.

A first spectral line (left) occurs at DC and has a magnitude corresponding to a magnitude of a residual sensitivity to the external or sensed magnetic field, ResBext, plus an undesirable offset voltage (no chopping) generated by the two magnetic field sensing elements 208, 210 of FIG. 19.

A second spectral line occurs at a frequency of fck and has a magnitude, Bcal, corresponding to a magnitude of the reference magnetic field generated by the two reference field coils 206a, 206b. This spectral line has already been shifted to the frequency fck by operation of the switching of the switching circuit 204.

Referring now to FIG. 21, a graph 430 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 430 includes two spectral lines when in the presence of the periodically reversing reference magnetic field generated by the periodic reversal of the current 202 by operation of the switching circuit 204.

The graph 430 is representative of the magnetic field signal, B, associated with the magnetic field sensor portion 400 of FIG. 19 taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the reference-field-sensing configuration.

Since the switching circuit 214 of FIGS. 12 and 19 merely acts as a pass through when the two magnetic field sensing elements 208, 210 are coupled in the reference-field-sensing configuration, the graph 430 has the same spectral lines as the graph 420 of FIG. 20.

Referring now to FIG. 22, a graph 440 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 440 includes two spectral lines when in the presence of a periodically reversing reference magnetic field generated by the periodic reversal of the current 202 by operation of the switching circuit 204.

The graph 440 is representative of the magnetic field signal, C, associated with the magnetic field sensor portion 400 of FIG. 19 taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the reference-field-sensing configuration.

As can be seen, the amplifier 216 adds an offset component, AmpOff, to the spectral line of FIG. 21 appearing at DC. Otherwise, the two spectral lines of FIG. 22 are the same as those of FIG. 21, but scaled according to a gain of the amplifier 216.

Referring now to FIG. 23, a graph 450 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 450 includes two spectral lines when in the presence of a periodically reversing reference magnetic field generated by the periodic reversal of the current 202 by operation of the switching circuit 204.

The graph 450 is representative of the magnetic field signal, E, associated with the magnetic field sensor portion 400 of FIG. 19 taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the reference-field-sensing configuration.

As can be seen, by operation of the switching circuit 224 of FIGS. 12 and 19, frequencies have been shifted.

A first spectral line (left) occurs at DC and has a magnitude, Bcal, related to the magnitude of the second spectral line of FIG. 22 and corresponding to the magnitude of the reference magnetic field generated by the two reference field coils 206a, 206b. This spectral line is shifted to DC by operation of the switching circuit 224.

A second spectral line occurs at a frequency of fck and has a magnitude related to the magnitude of the first, DC, spectral line of FIG. 22.

Referring now to FIG. 24, a graph 460 has a horizontal axis with a scale in arbitrary units of frequency and a vertical axis with a scale in arbitrary units of magnitude. The graph 460 includes one spectral line.

The graph 460 is representative of the magnetic field signal, G, associated with the magnetic field sensor portion 400 of FIG. 19 taken when the magnetic field sensing elements 208, 210 are repetitively and periodically coupled in the reference-field-sensing configuration.

As can be seen, by operation of the filter circuits 226, 228 of FIGS. 12 and 19, other spectral components of FIG. 23 have been removed, leaving only the a spectral line at DC having a magnitude corresponding to the magnitude, Beal, of the reference magnetic field. The spectral line of FIG. 23 is representative of the above-described reference-magnetic-field-responsive signal.

While circuits and techniques may be described herein in terms of calibration of the magnetic field sensor, it should be understood that the same techniques can be used to provide a self-test of the magnetic field sensor. Namely, the reference-magnetic-field-responsive signal portion, G, of FIGS. 12 and 19 can be examined, for example, by another processor, to identify if the signal is within acceptable limits.

Referring now to FIG. 25, in which like elements of FIG. 12 are shown having like reference designations, a magnetic field sensor 470 is like the circuit 200 of FIG. 12, except that the filter circuit 228 and the amplifier 219 of FIG. 12 are replaced by a switched capacitor circuit 476. The switched capacitor circuit 476 is more fully described below in conjunction with FIG. 26. However, let it suffice to say that the switched capacitor circuit 476 can provide a transfer function having sinx/x (sine) transfer function characteristics similar to the filter circuit 228 as well as other filter characteristics. The switched capacitor circuit 476 can also provide a bandwidth characterized by a unity gain bandwidth.

The switched capacitor circuit 476 can be the same as or similar to one of the switched capacitor filters shown and described in U.S. Pat. No. 7,990,209, issued Aug. 2, 2011, assigned to the assignee of the present invention, and incorporated by reference in its entirety herein.

The magnetic field sensor 470 includes a control circuit 478 having a clock frequency generator 480 configured to generate a redistribution clock signal 480a with a first redistribution clock frequency during a first time period and with a second different redistribution clock frequency during a second time period. In some embodiments, the clock frequency generator 480 is further configured to generate a sample clock signal 480b with a sample clock frequency, which can be the same frequency during the first and second time periods.

The switched capacitor circuit 476 is coupled to receive the redistribution clock signal 480a and also the sample clock signal 480b. The switched capacitor circuit 476 forms an integrator having a selectable unity gain frequency, wherein a first unity gain frequency is related to the first redistribution clock frequency during the first time period, and a second unity gain frequency is related to the second redistribution clock frequency during the second time period. Unity gain frequencies are described more fully below in conjunction with FIGS. 27-31. It will be understood that an integrator has a very high gain at DC.

In some embodiments, a bias circuit 482 can be coupled to receive the output signal 476a from the switched capacitor circuit 476, and configured to generate bias signal 482a, 482b that can drive or otherwise influence drive currents to the two Hall elements 208, 210. Thus, it will be understood that the bias signals 482a, 482b can influence sensitivity of the two Hall elements 208, 210.

Circuit elements within a box 472 correspond to a primary circuit path. The primary circuit path 472 is configured to generate an output signal, Vo, related to a measured magnetic field sensed by the magnetic field sensing elements 208, 210 when coupled in the above-described measured-field-sensing configuration. The primary circuit path has a so-called “circuit parameter,” for example, a sensitivity and/or a gain.

Circuit elements within a box 474 correspond to a feedback circuit path. The feedback circuit path 474 is configured to generate an output signal, VCAL, related to a reference magnetic field generated by the coils 206a, 206b and sensed by the magnetic field sensing elements 208, 210 when coupled in the above-described reference-field-sensing configuration. The feedback circuit 474 is also configured to generate the output signal 476a (also 482a, 482b in this embodiment) coupled to control the above-mentioned circuit parameter (i.e., sensitivity) of the primary circuit path 472.

The feedback circuit path 474 is included in a box 484 corresponding to a feedback loop 484. The feedback loop 484 also includes some elements of the primary circuit path 472.

As described above, the switched capacitor circuit 476 is coupled to receive the redistribution clock signal 480a. The redistribution clock signal 480a results in the switched capacitor circuit 476 having, in addition to the above-described unity gain frequency controlled by the frequency of the redistribution clock signal 480a, a notch characteristic, which has a notch frequency related to the frequency of the redistribution clock signal 480a. In turn, the frequency of the sample clock signal 480a can be related to the frequency of the redistribution clock signal 480a, e.g, a factor of 2n times the frequency of the redistribution clock signal 480a. In general, a lowest frequency notch of the notch characteristic occurs at the frequency of the redistribution clock signal 480a, and a higher frequency notch occurs at the frequency of the sample clock signal 480b.

In some embodiments, the second redistribution clock frequency occurring during the second time period following the first time period can be lower than the first redistribution clock frequency occurring during the first time period.

In some embodiments, the clock frequency generator 480 can be configured to generate the redistribution clock signal 480a with more than two redistribution clock frequencies at a respective more than two different times.

In some embodiments, the first time period can begin at a time proximate to a startup of the magnetic field sensor 470, and the second time period can begin at a time proximate to an end of the first time period.

In some embodiments, the magnetic field sensor 470 can be disposed proximate to a target object (not shown), and the magnetic field sensor 470 can be configured to sense a movement of the target object. For these embodiments, the first time period can begin at a time proximate to a first movement of the target object, and the second time period can begin at a time proximate to an end of the first time period.

In some embodiments, the circuit parameter of the primary circuit path 472 controlled by the feedback circuit 474 can be a sensitivity of the primary circuit path 476 to the magnetic field. To this end, the output signal 476a can control a sensitivity of the magnetic field sensing elements 208, 210 by way or the bias circuit 482 as described above. However, in other embodiments (not shown), the output signal 476a can control an amplifier gain, for example, a gain of the amplifier 216, to control a sensitivity of the primary circuit path 472 to achieve a similar result.

In some embodiments that control the sensitivity of the magnetic field sensing elements, the bias circuit 482 generates the bias signals 482a, 482b as a voltage signals. In other embodiments, the bias circuit 482 generates the bias signals 482a, 482b as current signals. The magnetic field sensing elements 208, 210 can be coupled receive the voltage signals or the current signals.

In some embodiments described more fully below in conjunction with FIG. 32, the circuit parameter of the primary circuit path 472 controlled by the feedback circuit 474 can include an offset voltage of the primary circuit path.

In some embodiments described more fully below in conjunction with FIGS. 30 and 31, the first unity gain frequency of the switched capacitor circuit 476 and the second unity gain frequency of the switched capacitor circuit 476 can be selected to provide loop stability.

In some embodiments, the magnetic field sensing elements 208, 210 comprise at least two Hall effect elements.

In some embodiments, the magnetic field sensing elements 208, 210 comprises at least two magnetoresistance elements.

As described above in conjunction with FIG. 12, the primary circuit path 472 can include the first switching circuit 212 and the second switching circuit 204, functions of which are described above in conjunction with FIG. 12.

Primary circuit path signals A, B, C, D, and F, shown and described above in conjunction with FIGS. 12-18, are also shown in FIG. 25. Operation of the primary circuit path 472, and signals A, B, C, D, and F therein, are the same as those described above in conjunction with FIGS. 12-18.

Feedback circuit path signal, E, is similar to the signal, E, shown and described above in conjunction with FIGS. 13 and 23. Feedback circuit path signals, G′, and G″, are similar to the signal, G, shown and described above in conjunction with FIGS. 13, and 24. However, the signals G′ and G″ undergo different filtering than the filtering provided by the filter 228 of FIG. 19. The signals G′ and G″ also tend to have slowly varying frequencies, unlike the DC frequency indicated in FIG. 24. Also, the signal, G′, carries information about the calibration signal, VCAL, while the signal, G″, carries information about how different the calibration signal, VCAL, is from the reference signal, VREF.

As described above in conjunction with FIGS. 12-18, the primary circuit path 472 can be time multiplexed to select and to process the above-described signal representative of the measured-magnetic-field-responsive signal portion during the measurement time periods, and the feedback circuit path 474 can be time multiplexed to select and to process the above-described signal representative of the reference-magnetic-field-responsive signal portion during the reference time periods interleaved with the measurement time periods.

The primary circuit path 472 can be configured to generate the output signal, Vo, as a first sensor output signal representative of the measured-magnetic-field-responsive signal portion. As described above in conjunction with FIGS. 12 and 19-24, the feedback circuit path 474 can be configured to generate the output signal, VCAL, as a second different sensor output signal representative of the reference-magnetic-field-responsive signal portion. In some embodiments, the output signal, VCAL, is internal to the magnetic field sensor 470 and is used as a self-calibration signal. In other embodiments, the output signal, VCAL, can be used as a self-test signal provided outside of the magnetic field sensor 470.

Referring now to FIG. 26, a switched capacitor circuit 500 can be used as the switched capacitor circuit 476 of FIG. 25. The switched capacitor circuit 500 can include a plurality of capacitors surrounded by a plurality of switches, forming an integrator arrangement.

In a first channel, switches 504a, 506a are coupled to one side of capacitor 502a. The switch 504a is coupled to receive a positive reference voltage (a threshold), VREF+, and is controlled by a sample clock signal, CLKS. The positive reference voltage, VREF+, can be the same as or similar to one side of the differential the reference voltage, VREF, of FIG. 25. The sample clock signal, CLKS, can be the same as or similar to the sample clock signal 480b of FIG. 25. The switch 506a is coupled to receive a common mode or bias voltage, VCM, and is controlled by a redistribution clock signal, CLKR. The redistribution clock signal, CLKR, can be the same as or similar to the redistribution clock signal 480a of FIG. 25.

Also in the first channel, switches 508a, 510a are coupled to the other side of the capacitor 502a. The switch 508a is coupled to receive the common mode voltage, VCM, and is controlled by the sample clock signal, CLKS. The switch 510a is coupled to a noninverting input of an amplifier 512, and is controlled by the redistribution clock signal, CLKR.

In a second channel, switches 504b, 506b are coupled to one side of capacitor 502b. The switch 504b is coupled to receive a negative reference voltage (a threshold), VREF-, and is controlled by the sample clock signal, CLKS. The negative reference voltage, VREF-, can be the same as or similar to one side of the differential the reference voltage, VREF, of FIG. 25. The switch 506b is coupled to receive the common mode voltage, VCM, and is controlled by the redistribution clock signal, CLKR.

Also in the second channel, switches 508b, 510b are coupled to the other side of the capacitor 502b. The switch 508b is coupled to receive the common mode voltage, VCM, and is controlled by the sample clock signal, CLKS. The switch 510b is coupled to an inverting input of the amplifier 512, and is controlled by the redistribution clock signal, CLKR.

In a third channel, switches 504c, 506c are coupled to one side of capacitor 502c. The switch 504c is coupled to receive a negative calibration signal, VCAL−, and is controlled by the sample clock signal, CLKS. The negative calibration signal, VCAL−, can be the same as or similar to one side of the differential the output signal, VCAL, of FIG. 25. The switch 506c is coupled to receive the common mode voltage, VCM, and is controlled by the redistribution clock signal, CLKR.

Also in the third channel, switches 508c, 510c are coupled to the other side of the capacitor 502c. The switch 508c is coupled to receive the common mode voltage, VCM, and is controlled by the sample clock signal, CLKS. The switch 510c is coupled to the noninverting input of the amplifier 512, and is controlled by the redistribution clock signal, CLKR.

In a fourth channel, switches 504d, 506d are coupled to one side of capacitor 502d. The switch 504d is coupled to receive a calibration signal, VCAL+, and is controlled by the sample clock signal, CLKS. The positive calibration signal, VCAL+, can be the same as or similar to one side of the differential the output signal, VCAL, of FIG. 25. The switch 506d is coupled to receive the common mode voltage, VCM, and is controlled by the redistribution clock signal, CLKR.

Also in the fourth channel, switches 508d, 510d are coupled to the other side of the capacitor 502d. The switch 508d is coupled to receive the common mode voltage, VCM, and is controlled by the sample clock signal, CLKS. The switch 510d is coupled to the noninverting input of the amplifier 512, and is controlled by the redistribution clock signal, CLKR.

Outputs from the first and third channels are in parallel, and outputs from the second and third channels are in parallel.

The amplifier 512 generates a differential output signal 512a, 512b.

A capacitor 514 is coupled between the non-inverting input of the amplifier 512 and the positive output side 512a of the amplifier 512. A capacitor 516 is coupled between the inverting input of the amplifier 512 and the negative output side 512b of the amplifier 512.

It should be understood that the switched capacitor circuit 500 is in the form of a differential integrator. It should also be understood that the switched capacitor circuit 500 provides a sinx/x (sine) type transfer function for which the first notch is related to a frequency of the redistribution clock signal, CLKR. It should also be understood that the switched capacitor circuit 500 provides a transfer function that has a unity gain frequency controlled in accordance with a frequency of the redistribution clock signal, CLKR. In general, the unity gain frequency is well within the notch frequency.

In operation, by changing the frequency of the redistribution clock signal, CLKR, the unity gain frequency can be changed. Because the switched capacitor circuit 500 is used in a feedback loop, e.g., the feedback loop 484 of FIG. 25, the speed or rate of self-calibration (or self-test) of the magnetic field sensor 470 of FIG. 25 can be related to a frequency of the redistribution clock signal, CLKR.

Referring briefly again to FIG. 25, in some applications, it is desirable, at some times, for example, at a times immediately after the magnetic field sensor 470 is powered up, to perform a self-calibration (or self-test) of the magnetic field sensor 470 rapidly. The rapid calibration can be achieved by way of increasing a bandwidth of the feedback circuit path 474, i.e., by increasing a unity gain frequency of the switched capacitor circuit 476. This effect is described more fully below in conjunction with FIGS. 27-31. However, if this increased bandwidth were maintained throughout operation of the magnetic field sensor 470, it will be understood that the resolution of the magnetic field sensor and noise performance of at least the feedback circuit path 474 would be degraded. Therefore, it is desirable, at other times, for example, at times when the magnetic field sensor 470 is already self-calibrated (or self-tested) and operational, to continue the self-calibration (or self-test) of the magnetic field sensor 470 with a smaller bandwidth, i.e., less rapidly. The less rapid self-calibration (or self-test) can be achieved by way of decreasing a bandwidth of the feedback circuit path 474, i.e., by decreasing a unity gain frequency of the switched capacitor circuit 476.

Accordingly, the clock generator 480 of FIG. 25 can be used to provide the redistribution clock signal 480a with different frequencies at different times. In some embodiments, the redistribution clock signal 480a has a first frequency immediately after the magnetic field sensor 470 is powered up, and a lower second frequency thereafter. In still some other embodiments, the redistribution clock signal 480 has a first frequency immediately after the magnetic field sensor 470 identifies a movement of a target object that is proximate to the magnetic field sensing elements 208, 210, and a lower second frequency thereafter.

In other embodiments, there can be more than two frequencies of the redistribution clock signal 480a depending on the application in which the magnetic field sensor 470 is used.

Referring again to FIG. 26, each one of the capacitors 502a, 502b, 502c, 502d and associated switches can be replicated (in parallel) in each particular channel depending on a number of phases of chopping of the magnetic field sensing elements 208, 210. Also, in order to keep the same circuit characteristics when the capacitors 502a, 502b, 502c, 502d and associated switches are replicated, the values of the capacitors 514, 516 can be scaled accordingly. In such arrangements, the sample clock signal, CLKS, can instead be a plurality of sample clock signals, each with the same frequency, but each having a different phase, wherein each phase controls switches of an associated one of the replicated switches for each channel that receives a sample clock as opposed to the redistribution clock. For a 4× chopping arrangement, each one of the capacitors 502a, 502b, 502c, 502d is replicated in four respective instances, resulting in sixteen capacitors, each surrounded by four switches. For a 2× chopping arrangement, each one of the capacitors 502a, 502b, 502c, 502d is replicated in two respective instances, resulting in eight capacitors, each surrounded by four switches.

The above described chopping arrangements are described in the above-mentioned U.S. Pat. No. 7,990,209, issued Aug. 2, 2011.

Referring now to FIG. 27, an exemplary feedback loop 520 has two circuit elements with a corresponding two transfer functions, AOL and β. The feedback loop can represent the feedback loop 484 of FIG. 25, wherein the output signal Vo of FIG. 27 corresponds to the signal 476a of FIG. 25. Referring briefly to FIG. 25, it is intended that the transfer function, AOL, correspond to a transfer function of the switched capacitor circuit 476, and it is intended that the transfer function, β, correspond to a transfer function of the rest of the circuits within the feedback loop 484 of FIG. 25.

Referring now to FIG. 28, a graph 522 has a horizontal axis with a logarithmic scale in arbitrary units of units of frequency and a vertical axis with a logarithmic scale in arbitrary units of gain. The graph 522 is representative of the transfer function, AOL, i.e., gain of the switched capacitor circuit 476 of FIG. 25 alone.

The switched capacitor circuit has a maximum gain of AOL, a unity gain frequency of fintegrator and a corner frequency of fintegrator divided by AOL. In some embodiments, the gain, AOL, is about 100 dB (i.e., 100,000), the unity gain frequency is about 100 Hz, and the corner frequency is about 100 Hz divided by 100,000. If the switched capacitor circuit 476 were a perfect integrator, then AOL would be infinite. However, infinite gain is not realizable. A range of AOL from about 80 dB to about 120 dB can be used

Referring now to FIG. 29, a graph 524 has a horizontal axis with a logarithmic scale in arbitrary units of units of frequency and a vertical axis with a logarithmic scale in arbitrary units of gain. The graph 524 is representative of the transfer function, β, i.e., gain of the other circuit elements within the feedback loop 484 of FIG. 25.

The other circuit elements combined have a maximum gain of β, and a corner frequency of fβ. In some embodiments, the gain, β, is about 0 dB (i.e., 1) and the corner frequency is about 100 kHz.

Referring now to FIG. 30, a graph 526 has a horizontal axis with a logarithmic scale in arbitrary units of units of frequency and a vertical axis with a logarithmic scale in arbitrary units of loop gain. The graph 526 is representative of a product of the transfer functions, AOL and β, i.e., loop gain of the feedback circuit 484 of FIG. 25 and of the feedback circuit 520 of FIG. 27.

The graph 530 is representative of the loop gain of the feedback circuit 484 of FIG. 25 during a first time period, for example, beginning at a time of start-up of the magnetic field sensor 470 of FIG. 25. However, the graph 530 is representative of only a part of a frequency response of the feedback circuit 484 of FIG. 25. In particular, the graph 530 shows the transfer function without the sinx/x (redistribution/sampling) part, a notch from which would be at a higher frequency than represented in the graph 530.

The feedback loop has a maximum open loop gain of AOL times β, a unity gain frequency or fintegrator times β, and a corner frequency of fintegrator divided by AOL. In some embodiments where β is about one, the open loop gain is about 100 dB (i.e., 100,000), the unity gain frequency is about 100 Hz, and the corner frequency is about 100 Hz divided by 100,000.

At the frequency, fβ, the pole of the graph 524 of FIG. 29 occurring at the frequency, fβ, causes the transfer function 532 to change slope and to undergo additional phase shift. In order for the feedback loop 520 of FIG. 27 or the feedback loop 484 of FIG. 25 to have a phase margin of at least forty-five degrees, at the frequency fβ, where additional phase shift is incurred, the gain must be less than zero dB, as is shown.

Comparing the graph 530 to the graph 522 of FIG. 28, it will be appreciated that the unity gain frequency of the graph 530 is related to fintegrator, which, as indicated in FIG. 28, is controlled by the switched capacitor circuit 476 of FIG. 25 and by the frequency of the redistribution clock signal 480a in particular. Thus, by changing the unity gain frequency of the switched capacitor circuit 476, the loop gain of the feedback loop 484 can be changed accordingly.

Referring now to FIG. 31, a graph 540 has a horizontal axis with a logarithmic scale in arbitrary units of units of frequency and a vertical axis with a logarithmic scale in arbitrary units of gain.

The graph 540 is representative of the open loop gain of the feedback circuit 484 of FIG. 25 during a second time period, for example, after the first time period described above in conjunction with FIG. 30. As in FIG. 30, the graph 540 is representative of only a part of open loop gain of the feedback circuit 484 of FIG. 25. In particular, the transfer function 540 shows the transfer function without the sinx/x (redistribution/sampling) part, a notch from which would be at a higher frequency than represented in the graph 540.

In the graph 540, the unity gain frequency is altered from that of the graph 530 of FIG. 30 by changing a frequency of the redistribution clock signal 480a of FIG. 25 . . . . In some embodiments, the open loop gain is about 100 dB (i.e., 100,000), the open loop unity gain frequency is about 30 Hz, and the open loop corner frequency is about 30 Hz divided by 100,000.

Referring now to FIG. 32, in which like elements of FIG. 25 are shown having like reference designations, another exemplary magnetic field sensor 560 can include a primary circuit path 562, which can be the same as or similar to the primary circuit path 472 of FIG. 25. Here, however, the primary circuit path 562 is shown without the sine filter 222. Also, the switching circuit 204 is a bypass and the coil current is set to zero as in FIG. 13.

Comparing FIG. 32 with FIG. 25, it will be noticed that the sinc filter 222 does not appear in FIG. 32. The sinc filter 222 is intended to reduce offset components, which are already removed by operation of the feedback in FIG. 32. However, in other embodiments of the magnetic field sensor 560, the sine filter 222 can be included. Advantageously, removal of the sine filter 222 can result in a faster magnetic field sensor.

The magnetic field sensor 560 includes a feedback circuit path 564 different than the feedback circuit path 474 of FIG. 25. The feedback circuit path is included in a feedback loop 584, which also includes the amplifier 216.

The feedback circuit path 564 can include a feed through circuit 574 arranged to directly pass the signal, C. A signal, C′, an offset voltage signal, Voff, results as an output signal from the magnetic field sensor 560. In some embodiments, the output signal, Voff, is internal to the magnetic field sensor 560 and is used as a self-calibration signal. In other embodiments, the output signal, Voff, can be used as a self-test signal provided outside of the magnetic field sensor 470. It will be understood that the output signal, Voff, approaches zero under proper steady state conditions.

The magnetic field sensor 560 can include a switched capacitor circuit 566. The switched capacitor circuit 566 can be the same as or similar to the switch capacitor circuit 476 of FIG. 25. Here, however, the switched capacitor circuit 566 is coupled to receive the offset voltage signal, Voff, in place of the calibration signal, VCAL, of FIG. 25, and the reference signal, VREF, is set to zero.

The magnetic field sensor 560 can include a control circuit 568 having a clock generator 570 configured to generate clock signals 570a, 570b. The control circuit 568, the clock generator 570, and the clock signals 570a, 570b can be the same as or similar to the control circuit 478, the clock generator 480, and the clock signals 480a, 480b of FIG. 25.

The switched capacitor circuit 566 is configured to generate an output signal 566a, also referred to herein as a signal, C″. From discussion below, it will be understood that the output signal 566a (C″), as well as the output signal, Voff (C′), generated by the filter 226, are similar to the signal, C, of FIG. 16. However, the signals, C′, C″, include additional filtering provided by the filter 226. Thus frequency components above DC will be reduced.

In some embodiments, the magnetic field sensor 560 operates with 2× chopping. FIG. 1A, graph 32, is representative of the signal, C, after the amplifier 16 of FIG. 1 (and after the amplifier 216 of FIG. 32) when 2× chopping is used. The 2× chopping results in an offset component only at DC. This component can be removed by the feedback circuit path 564. The signals, C′, C″, can have a similar DC portions to that graph 32 of FIG. 1A. After the feedback circuit has reached a steady state, the DC portion of the signals C, C′ becomes zero.

In some alternate embodiments, the magnetic field sensor 560 operates with 4× chopping. FIG. 16 is representative of the signal, C, after the amplifier 216 of FIGS. 12, 13, and 32 when 4× chopping is used. The 4× chopping results in an additional offset component. Embodiments that use 4× chopping require extra circuitry (not shown) to remove the additional offset component.

The magnetic field sensor 560 can include an interface circuit 572 coupled to receive the output signal 566a and configured to generate an offset control signal 572a. The amplifier 216 can be coupled to receive the offset control signal 572a. With this arrangement, the offset control signal 572a can reduce or eliminate offset voltage from the primary circuit path 562.

In the magnetic field sensor 560, the switched capacitor circuit 566 can operate with at least the two unity gain bandwidths described above in conjunction with FIGS. 25-31.

It should be appreciated that, in some embodiments, the circuit 574 can be eliminated and straight through paths can be provided in its place.

It should also be understood that a single integrated magnetic field sensor can have the gain (i.e., sensitivity) calibration features of the magnetic field sensor 470 of FIG. 25 and also the offset calibration features of the magnetic field sensor 560 of FIG. 32. In these embodiments, a circuit can be altered during operation of the magnetic field sensor to operate at some times as the feed through circuit shown as the circuit 574, or to operate at other times as the switching circuit 224 of FIG. 25. In these embodiments, it may be advantageous to have both the switched capacitor circuit 476 of FIG. 2 with the bias circuit 482, and also to have the switched capacitor circuit 566 of FIG. 32 along with the interface circuit 572. Thus, in some embodiments, a magnetic field sensor can provide the circuit topology of FIG. 32 along with the circuit topology of FIG. 25. This combined arrangement can provide a self-calibration (or self-test) of a sensitivity and also a self-calibration (or self-test) of an offset voltage of a combined magnetic field sensor.

All references cited herein are hereby incorporated herein by reference in their entirety.

Having described preferred embodiments, which serve to illustrate various concepts, structures and techniques, which are the subject of this patent, it will now become apparent to those of ordinary skill in the art that other embodiments incorporating these concepts, structures and techniques may be used. Accordingly, it is submitted that that scope of the patent should not be limited to the described embodiments but rather should be limited only by the spirit and scope of the following claims.

Cesaretti, Juan Manuel, Romero, Hernan D.

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